his comes in the form of an HTML page with links to every component, so you will need to view it in your web browser. (I use Chrome and it doesn't seem to be working correctly, but when opened in IE its fine.)
2) Included in each help topic for each component is the Inputs and Outputs descriptions and data types.
3) You supply the data. What you supply and how you supply it is for you to decide. There are umpteen different ways. Are you asking for a list of those ways for each input?
4) Points can either be Rhino objects or 3D co-ordinates. To create a point you can use any of these methods, but it mostly comes down to user preference. I like using Panels as this displays outside of the component.
5) Because of the nature of vectors they represent magnitude and direction but they don't have an independent location, so there is a component that will display vectors in Rhino.
6) The user.
7) There is a Primer on the front page. Here you find the Basics, but because GH is ever evolving in its current beta state you might find things that aren't relevant any more or simply don't work the same. And here is the reason why nobody is writing an update because it could be soon out of date.
8) Importing images by either dragging them from explorer onto the canvas or right click context menu Image...
9) Single line = Single Item of Data. Double line = Multiple items of data on the same Branch. Dashed Double Line = Multiple Data on Multiple Branches.
10) User preference
11) Toolbar management is probably the bane of David's life. Most things are logically placed. For example the Curve Tab, Primitives are any simple curve types that you are creating from scratch. Similarly Splines is for more complex curve types created from scratch. Analysis is where you find components that are finding answers supplied by curves, control points, curvature, parameters, end points etc. Division is a subset of this category but has a group of its own. And Utilities is where you find curve related actions that you want to perform, offsetting, rebuilding projecting, exploding etc.
12) I would image it would have been the Point On Curve component in Curve>Analysis. Why that group? You are not putting a point on a curve you are analysing a curve for the location of a point based on some parameters that you are supplying. For example "what is the mid point?"
I hope this goes some way towards answering you questions. No doubt this will have generated more so don't be afraid to ask, it took me several releases of Explicit History (aka Grasshopper) before I realised what the egg did, it never occurred to me that I could put my objects into Rhino when I was finished. Or the fact that I could use panels to 'see' data outputs.
Al the best,
Danny…
Added by Danny Boyes at 3:48am on December 9, 2010
can work in any node of a given hierarchy tree (loaded in your work session) by making the node "active". "Nodes" can be other things as well (like workplane, clip definitions etc).
Why to do that weird thing? Well, think any design being "flat" > meaning that all objects are placed in a single file (and in a single layer). Not that good > although the items are present you barely can handle them (because power is nothing without control, he he).
Let's go one step further: we can start classifying objects in "groups" (like a directories/files organization in any O/S). This means, in MCAD speak, creating assemblies (a void thing kinda like a directory) that contain components/entities (kinda like files).
Several steps further we end up with severely nested "arrangements" of entities (an assembly could be parent of something and child of something else).
For instance, it could be rather obvious the logical classification of a "geodetic" (so to speak) structure like this : a 40000m2 "hangar" defining some thematic park.
I mean : a void master that owns 4 equal void segment sets that own 4 "legs" that own various geodesic structural members + cables + membranes + you name it etc etc.
Each "leg" owns the concrete base (Shared) and a rather complex set of objects.
Notice that some tensile membrane "fixture" combos (see above)...act as perimeter light fixtures as well...meaning that the membrane tension plate may could be a child of a void "light" parent...or may could be a "stand alone" assembly etc etc.
These arrangements can be internal (belonging in, say, a x node within the current active file) or external (belonging in a y node within another file). If they deal with the same (topologically speaking) object they define clusters of Shared entities (or variations)- where only the view transformation matrix changes (in the simple scenario, he he). For instance the disk shown above is a Shared Assembly that owns the bolts, the plates, the tension member etc etc. Selective Instancing allows modifying some attributes without affecting the topology (i.e. the geometry).
The whole (terrible) mess is controlled by some tree like "dialog" (in Catia is "transparent") that is called Structure Browser. By controlled I mean (1) display/display mode with regard any tree member combo/selection set (assembly and/or component) in any View (2) clip state control (3) active status (for modifications/variations) (4) workplane control (5) drag and drop ownership control (6) ....
Now...what if I would chan…
rectly except for the first material in a series. See attached image... Here is my code:
Private Sub RunScript(ByVal M As Object, ByVal C As Color, ByRef AddName As Object, ByRef AddMat As Object, ByRef AddBool As Object, ByRef baseName As Object, ByRef newMatName As Object)
Dim z As String = "newMatName" Dim y As String = "BaseName" Dim x As Integer = 0 Dim nRestore As String Dim mTemp As Rhino.DocObjects.Material
mTemp = CType(M, Rhino.DocObjects.Material) y = mTemp.Name Dim nTemp As String
If mTemp.Name.Contains("_MOD_R") = False Then
nRestore = mTemp.Name nTemp = mTemp.Name & "_MOD_R" & C.R & "_G" & C.G & "_B" & C.B mTemp.Name = nTemp z = nTemp mTemp.DiffuseColor = C
If Doc.Materials.Find(nTemp, True) < 0 Then
Doc.Materials.Add(mTemp) x = x + 1 AddName = nTemp AddMat = mTemp
End If
mTemp.Name = nRestore
End If
newMatName = z
AddBool = x BaseName = y
End Sub
1) I have checked that all of the materials I am calling by name exist in the document and that data matching is correct. There doesn't seem to be anything special about the offending material except that it is always the first material that was added to the document by my script.
2) The main thing I was missing in the previous script was the "doc.Materials.Add()" -- how on earth should I have known that existed? Even a search for "doc.Materials" in the Rhinocommon SDK doesn't turn that up. I'm having a very hard time using the SDK to my advantage, it seems not to correlate to the actual code I need to write.
2b) Perfect example... now I am trying to rewrite my other component (which exposes all of the document materials) to set a few objects manually in Rhino with the Materials I want to use as templates. Now I am trying to find out how to access the material assigned to an object. Seems easy, but it's clearly not a Property, and I can't find an appropriate Method in either the Objects or Materials classes.
3) One of my problems originally, when feeding the component one material and multiple colors, was that the nTemp variable was not resetting properly for the second color. Same thing if I duplicated the material to match the list of colors. It would create a material on the first pass but concatenate "_MOD_R_G_B" in each subsequent pass and be caught by my String checker. Why is that? I thought that the nTemp Name variable would be reset in each pass by the line "mTemp = CType(M, Rhino.DocObjects.Material)" and "nTemp = mTemp.Name" combination.
Does the mTemp material somehow carry over its properties in each successive pass? That's why I added the nRestore to be sure each pass reset the name back to the original.
Still, I wonder if there is some problem with the way I am conceptualizing this that is causing the first material to be the same as the input material.
Thanks for your help on this...
Cheers,
Marc…
this occasion, but it could be converted for DT in no time). Requires some minutes more as regards ... some things, but the usual update is due to some days.
Bad news: it's C#
Good news: User's Manual :
1. That thing (the C#, not me) after sorting (in a "sequential way", so tho speak) the panels (their order was chaotic) allows you to start the massacre by locating a focus of interest (and the user controllable +/- Range derived from it).2. The Range is variable (obviously) and takes care not to exceed the indices of the panel list (OK, that's elementary).
3. If you click the right button (Sadistic Q: where is it? he he) things are deleted and a new constantly self-updating list is your new List. Thus the massacre of panels is totally controllable. An autoZoom thing is also included (free of charge, but it's a bit nerve braking). Zoom factor is variable as well.
4. Then you move over (via the index slider) and start the massacre again. Notice the change of Range.
5. If you turn begin to false (initialization) and then begin to true > start all over again.
6. The other C# thing allows you to increment the index slider in a rather more convenient way. It's a bit weird: it uses delegates (A delegate is an object that knows how to call a method) and events (An event is a construct that exposes just the subset of delegate features required for the broadcaster/subscriber model - but don't ask what this means, he he) in order to talk with your slider (with a defined NickName) and perform the required value control.
NOTE: without realizing it you've just (indirectly) asked one of the most important questions even exposed in this Noble Forum. I hear you : what question? Well ... wait some days for the mother of all threads: "Total control in collections on a per Item basis"
may the Force (the dark option) be with you (and me)
best, Peter…
should follow the instruction which mostapha has wrote in https://github.com/mostaphaRoudsari/ladybug/blob/master/resources/I...
Instructions for Installing Ladybug + Honeybee: (Follow steps 1-6 for basic functionality and 1-11 for full functionality) 0. If you have an old version of LB+HB, download the file here (https://app.box.com/s/ds96em9l6stxpcw8kgtf) and open it in Grasshopper to remove your old Ladybug and Honeybee version. 1. Make sure that you have a working copy of both Rhino and Grasshopper installed. 2. Open Rhino and type "Grasshopper" into the command line (without quotations). Wait for grasshopper to load. 3. Install GHPython by downloading the file at this link (http://www.food4rhino.com/project/ghpython?ufh) and drag the .gha file onto the Grasshopper canvas. 4. Select and drag all of the files in the "userObjects" folder (downloaded with this instructions file) onto your Grasshopper canvas. You should see Ladybug and Honeybee appear as tabs on the grasshopper tool bar. (If you are reading this instruction on github you can download them from http://www.food4rhino.com/project/ladybug-honeybee) 5. Download the files at this link (https://app.box.com/s/bh9sbpgajdtmmystv3n4), unzip them and copy the contents to both C:\ladybug and C:\Users\[yourUsername]\AppData\Roaming\Ladybug. 6. Restart Rhino and Grasshopper. You now have a fully-functioning Ladybug. For Honeybee, continue to the following: 7. Install Radiance to C:\Radiance by downloading it from this link (https://github.com/NREL/Radiance/releases/download/4.2.2/radiance-4...) and running the exe. 6. Install Daysim to C:\DAYSIM by downloading it at this link (http://daysim.ning.com/page/download) and running the exe. 8. Install Energy Plus 8.1 to C:\EnergyPlusV8-1-0 by going to the DOE website (http://apps1.eere.energy.gov/buildings/energyplus/energyplus_downlo...), making an account, going to "download older versions of EnergyPlus, selecting 8.1 and running the exe. 9. Copy falsecolor2.exe (http://pyrat.googlecode.com/files/falsecolor2.exe) and evalglare.exe (http://www.ise.fraunhofer.de/en/downloads-englisch/software/evalgla...) to C:\Radiance\bin 10. Download the OpenStudio Libraries (https://app.box.com/s/y2sx16k98g1lfd3r47zi) and unzip them to C:\ladybug\OpenStudio. 11. You now have a fully-working version of Ladybug + Honeybee. Get started visualizing weather data with these video tutorials (https://www.youtube.com/playlist?list=PLruLh1AdY-Sj_XGz3kzHUoWmpWDX...).
It works for me..
Agus…
Python and install it and it should work fine.
2. You still see the image above in case 1 however you have GHPython already installed. What about that?
In this case probably the GHA component is blocked. Find GHPython.GHA on your system (usually at: C:\Users\%username%\AppData\Roaming\Grasshopper\Libraries) . Right click, go to properties and select unblock.
To make sure that GHPython is working fine on your system open the attachment file (testGHPython.gh). You should see something similar to the image below on your screen when you open the file:
If you see the something similar you should be fine to go! Try to open one of the example files.
3. You have Ladybug running but in some of the case the output is missing. You see something similar to this:
or this
This one is because you are using old version of GHPython. Close the file without saving. Download the new version and install it and re-open the file. It should work fine now.
Hope it helps,
Mostapha
…
the mesh into long strips 1 quad wide.
*I did make an alternative icon for this, but opted for the tamer one in the end ;)
The Unroller component goes along the strip face by face, rotating it into a single plane.
Note that this component will still give a result even if you supply it with non planar quads - it will just fold them along a diagonal. However, if the faces are significantly non-planar, then it won't work as well for fabricating from a smooth strip of sheet material, so it is better to try and make sure your planarizing in the relaxation part is working well.
The Unroller component also has a T input which allows you to unroll only part of the mesh at a time. This is mainly for animation purposes, and most of the time you will probably just want to leave it set at 1.
At the moment the unroller is limited to working with open strips, so if your strip forms a closed loop, you will have to split it first. Later releases should include an automatic 'loop snipper'.
The final part of the definition then takes all these strips, orients them into the XY plane, and does some very basic layout.
It's then up to you to label, add tabs, nest, laser cut and assemble!
Because of the subdivision, each strip should have an even number of quads, which can also be useful for generating interlocking tabs by offsetting alternate groups of edges. I'll try and post an example of this soon.
I hope this is helpful. It was my intention when making this that it could be a relatively quick and easy way of making smooth curved structures out of sheet material, (I'm thinking card, polypropylene, metal, thin plywood...) with a lot less fixing/connecting work than doing a similar shape with individual panels.
Thanks to all the participants in these long-running threads:
http://www.grasshopper3d.com/forum/topics/how-to-create-nodesbone
http://www.grasshopper3d.com/forum/topics/skeletal-mesh*
which inspired this work, especially some of the comments by Ivan Kiryakov, Wiktor Kidziak, Giulio Piacentino, Andrew Haas and Mårten Nettelbladt.
*note also that the meshes generated using this definition can be used for developable strips, because they have the even-valence property.
I was also inspired by these papers:
http://www.cs.jhu.edu/~misha/Fall09/Liu06.pdf
http://www.geometrie.tugraz.at/wallner/strip.pdf…
lName, signalValue, operationMode):
sigV=signalValue
if sys.version_info[0] == 3:
if type(signalName) is str:
signalName=signalName.encode('utf-8')
if type(signalValue) is bytearray:
sigV = (ct.c_ubyte*len(signalValue))(*signalValue)
if type(signalValue) is str:
signalValue=signalValue.encode('utf-8')
sigV = (ct.c_ubyte*len(signalValue))(*signalValue)
else:
if type(signalValue) is bytearray:
sigV = (ct.c_ubyte*len(signalValue))(*signalValue)
if type(signalValue) is str:
signalValue=bytearray(signalValue)#<========This is line 1052
sigV = (ct.c_ubyte*len(signalValue))(*signalValue)
sigV=ct.cast(sigV,ct.POINTER(ct.c_ubyte)) # IronPython needs this
return c_WriteStringStream(clientID, signalName, sigV, len(signalValue), operationMode)
It displays the following error:
Program started
Connected to remote API server
Runtime error (TypeErrorException): unicode argument without an encoding
Traceback:
line 1052, in simxWriteStringStream, "C:\Program Files (x86)\V-REP3\V-REP_PRO_EDU\programming\remoteApiBindings\python\python\vrep.py"
line 70, in script
Any hint?…
are hotter than the least overlapped parts.
I'm trying to create gradients when overlapping between closed surfaces occur. The gradient goes from the center of the most overlapped figure to the edges of the least overlapped figures.
To help understand how I'm thinking it, I will first show you my solution for one figure.
As I said in the title, it's kind of a pseudo gradient. It's a way of organising areas (rings) inside of the geometry. To achieve this I thought in creating a series of rays that then can be divided in segments, in this case 3 segments of same lenght per ray, I could get more resolution in the gradient by dividing in more thus creating more rings...
in this picture the rays are in dark red and go from the center to 4 points in the perimeter, if I wanted more resolution I could have more rays, but with this simple figure 4 is enough
the rings are in a gradient of colors from the center to the perimeter, lighter in color each time:
so when I have 2 overlapping geometries
the center of the gradient should be on the center of the most overlapped part (in red) and go to the perimeter of the pink parts
for the red figure I draw the rays from the center to its perimetry. and for the pink figures the gradient should go from the parts that are in contact with the red figure to the perimeter, something like this:
still that is something I did with rhino and it's pretty intuitive...
the problem gets worse when i have more figures and more "heat centers"
like in these examples
maybe the approach should not be with rays to create the rings... maybe with offsets..
not sure if it's not too complicated to achieve in grasshopper and maybe there's another way of creating a gradient with multiple focuses...
would aprecciate any help
cheers…
phere with the maximum number of triangles but not much than a defined threshold.
I scaled that mesh just to fit Rhino grid, but it is not mandatory. What is useful, is to scale not uniformly the mesh (Scale NU). It could be done after cellular modifier applied or before or before and after. The 3 options are possible in the script. If you don’t need them just put 1 in scale sliders.
Ellipsoid mesh is the populated with points, I put 2 independents populations to randomize a bit further. For each vertices of the mesh the closest distance from the populated points is calculated.
Here is an illustration in color of this distance.
This distance is then used to calculate a bump. If domain for bump is beginning with negatives values to 0, it carves the mesh. Instead it bumps/inflates it.
Some images to illustrate the difference with populating 100 points with one or two populations.
Here some images to illustrate the application of scale before carving or after.
Next phase apply noise. At the moment I don't find it good.…